The present invention relates to roof tiles, roof coverings and methods of making and installing same. The roof tiles of the present invention are insulating roof tiles that are lightweight, highly fire resistant, strong and durable. The roof tiles to which the present invention pertains are those that are of a size common in the industry and which are used to cover a roof structure by arranging a plurality of such tiles in overlapping relationships to each other. The industry standards for roof tiles of the type to which the present invention relate are typically 15 to 20 inches long (along the roof pitch), 10 to 20 inches wide and 1 to 2 inches thick, all depending on the shape of the tile and the aesthetic appearance desired. Such tiles are not load-bearing elements of a roof structure, but are themselves a roof structure load.
As used throughout, the terms “roof tile” and “tile”, unless otherwise specified, mean an individual element generally of the dimensions set out above designed to be arranged, along with a plurality of like elements, in overlapping relationship to each other to form a waterproof covering or membrane over a roof structure.
Tiles of various compositions have been used since ancient times to provide a protective membrane over building roof structures of all kinds.
Fire resistant roof tiles are typically made of clay, cement or metal. Although aesthetically, clay and cement tiles are preferred, their major drawbacks are that they are extremely heavy and very fragile, making installation difficult and expensive and requiring more robust support structures than for known lighter roof coverings. On the other hand, clay and cement tiles have the advantage of durability and fire resistance. The present invention provides a roof tile that has the durable and fire resistant qualities of cement and clay while being as much as 40% lighter and vastly stronger.
The present invention comprises a roof tile of industry standard size having a foam core covered with a strengthening material (e.g., fiberglass mesh) and a thin outer cement-based protective coating (cured cement slurry). The cement-based protective coating includes one or more additives that impart excellent water repellant properties to the tile surface and increases its strength, durability and aesthetic appeal. The tile of the present invention has exceptional strength for its weight, which decreases shipping costs, virtually eliminates breakage during shipping and installation and requires only normal roof support structures.
In one embodiment, a cement-based slurry is applied to a mesh-covered foam core and cured to hardness, forming a non-porous coating that inhibits the intake of moisture thereby preventing deterioration from freezing/thaw cycles that are the bane of clay and cement tiles. In addition, the foam core of the tiles of the present invention provide greater insulating properties than cement or clay tiles, keeping interiors warmer in the winter and cooler in the summer. Although the tiles of the present invention are significantly lighter than clay or cement tiles, they provide greater strength and the same or greater fire resistance.
The roof tile of the present invention is lightweight, strong, has a high fire-resistance rating and a high insulation rating and can be easily formed into various cross-sectional shapes to increase aesthetic appeal and offers ventilation to the underside of the tiles. Thus, a roof tile, roof tile system (covering) and method of making and installing the same are provided in accordance with the invention, providing several structural, manufacturing and installation advantages.
Referring to
While the particular shape of foam core 12 illustrated has certain advantages as more fully described below, many other shapes are possible within the teachings of the invention, with each shape having particular advantages and/or aesthetic appeal. Shapes that are primarily flat and shapes that are arcuate or include arcuate sections are all within the teachings of the invention.
Referring to
A first core side wall 33 has an upper edge 34 coextensive with the first upper surface lateral edge 17 and a spaced-apart lower edge 36 coextensive with the lower surface first lateral edge 24. A second side wall 38 (which is a mirror image of side wall 33 but not shown) spaced apart from the first side wall 33 has an upper edge 39 coextensive with the upper surface second lateral edge 18 and a spaced-apart lower edge 41 (
The foam core member 12 has, at one end, a first slot forming end member 28 and, at the other end, a second slot forming end member 29. A first slot 43 (
A second slot 53 (
The slots 43 and 53 in end members 28 and 29, respectively, play an important role in connection with the cement-based protective coating in forming reliable inter-tile connections as more fully described below.
In ways known in the art, the foam core 12 can be formed in a variety of shapes including, but not limited to, substantially flat to simulate a cedar or slate roof shingle (
A wide range of aesthetic choices are possible by virtue of the ease of forming the foam core 12 and the ability to color and texture the protective coating. This is in addition to the exceptional performance of the tile as a weather barrier, an insulator, an insect resister and a fire retardant. In all of these respects, the tile 11 of the present invention equals or out-performs equivalent tiles made of clay or cement while being anywhere from 30 to 60 percent lighter and significantly more damage resistant during transportation and installation. The tiles 11 are so strong that they easily support the weight of installers standing on them during installation. At the same time, the tiles can be nailed to the underlying roof structure without pre-drilling and without breaking or cracking. Further, they can be trimmed to size where needed with a handsaw.
In one embodiment, the foam core 12 is expanded polystyrene (EPS). EPS is generally produced from a mixture of about 95% polystyrene and 5% gaseous blowing agent (e.g. pentane). Other types of foam such as high density foam, Styrofoam™, blue board, polystyrene, injection foams, MDI monomer, polyurethane resins, extruded foam, expanded polystyrene, expanded plastic foam, expanded polyethylene and nylon can be used. As used herein unless indicated otherwise, the term “foam” includes EPS and its suitable substitutes.
In one embodiment, the foam core 12 is cut from a large block of foam with a computer-driven hot wire cutting machine specifically designed for such operations. In other embodiments, the foam core 12 can be extruded, molded or cast. It is the ability of the foam to be formed into a desired shape and size that gives the tile 11 of the present invention its ability to emulate the aesthetic appearance and shape of known roof tiles, as well as novel shapes not easily formed of clay or cement, while offering superior performance characteristics as pointed out above and more fully described below.
After the foam core member 12 is formed, including end member slots 43 and 53, the strengthening material 13 (
Referring to
Referring to
In one embodiment of the invention, in applying the mesh sheet 76 to the core 16, the first end edge 77 of mesh sheet 76 is located and secured at the approximate midsection of lower surface 22, with the mesh sheet lateral edges 79 and 81 immediately adjacent to lower surface first lateral edge 24 and lower surface second lateral edge 26, respectively. The sheet 76 is drawn towards the second core end member 29 and draped over the distal end 57 of second major extension 56 (
Referring also to
It will be appreciated by those skilled in the art that the geometry of a foam core member 12 that does not have generally parallel side walls and/or parallel end edges will require a mesh sheet 76 of appropriate geometry to cover the foam core upper surface and lower surface within the boundary of the lateral edges and end edges. In some cases, the mesh sheet 76 may have to be applied in more than one piece.
For those embodiments of the roof tile 11 of the present invention that include a convex arcuate section 15 (
After mesh materials 71 and 76 are secured to the foam core 12, a cement-based slurry is applied to cover foam core surfaces 16 and 22 (all the way to and including end edges 19 and 21) and first side wall 33 and, optionally, second side wall 38. When cured to hardness, the cement-based slurry becomes protective coating 14 (
A cement coating is applied to the surface of the foam and may provide one or more of the following general attributes: appearance, protection and strength. Specific attributes may include high compressive and tensile strength, corrosion resistance, temperature durability, inertness and colorfastness.
The protective coating is made from a cement mixture. Specifically, the mixture may include, in addition to cement, one or more of the following components that are added to water:
In one embodiment of the invention, the cement coating comprises the following dry ingredients expressed in relative amounts by weight:
34% cement; 58% sand; 5% redispersible binder and 3% lime. It will be understood by those skilled in the art that these relative percentages will adjust should the coating material have other components added, although their relative amounts will stay fairly constant.
Other embodiments are within the following ranges: cement 20-35%; sand 55-71%; redispersible binder 4-5% and lime 3-5%. When used, the resin and saline-based efforescence-reducing and waterproofing agent constitutes a fraction of 1%, as does the anti-efforescence compound.
It will be appreciated by those skilled in the art that small deviations from the percentages expressed above will not materially alter the overall performance of the protective coating and are therefore within the scope of the invention.
In some embodiments, it may be advantageous to coat the entire tile. For example, where condensation may collect on the interior surface of the tile, a coating material may help protect the integrity of the foam. Another alternative is to apply the coating to only the surface of the foam that will be exposed to the elements. Also, different coatings may be applied to different surfaces to optimize the resilience of the tile. For example, in one embodiment, a less durable coating may be applied to surfaces that are not exposed to the elements, while a more durable coating is applied to the surfaces that are so exposed. Also, one or more layers of the same or different coatings may be used. For example, in another embodiment, the mixture shown in Table 1 is used to form a slurry that is applied to the mesh-covered foam core member 12 in two separate applications. A ⅛″ coating (for example) is applied to the top surface and allowed to cure. A second 1/16″ thick coating is applied to the top surface and the bottom surface and allowed to cure. Other combinations of thicknesses of a first coating and a second coating are within the teachings of the invention.
Referring to
The protective coating 86 fills in the end member slot 43, covers the first major extension member 46 and first minor end extension 51, forming a first L-shaped flange 88 having a first flange engagement member 90 extending generally along the width of the tile 11 and having a first flange engagement surface 89 and a distal end 92. Also formed is a first flange abutment member 93 generally perpendicular to the first flange engagement member 89 and having a first abutment surface 91 generally perpendicular to the first engagement surface 89. The flange surfaces 89 and 91 and end 92 are contiguous with and part of upper surface protective coating 86.
Likewise, the protective coating 86 fills in the second end member slot 53, covers the second major extension member 56 and second minor end extension member 59, forming a second L-shaped flange 94 having a second flange engagement member 95 extending generally along the width of the tile 11 having a second flange engagement surface 96 and a distal end 98. Also formed is a second flange abutment member 99 generally perpendicular to the second flange engagement member 95 and having a second flange abutment surface 97 generally perpendicular to the second flange engagement surface 96. The flange surfaces 97 and 96 and end 98 are contiguous with and part of upper surface protective coating 86.
The first generally L-shaped flange 88 and second generally L-shaped flange 94 are opposite facing (flange 88 having its engagement surface 89 facing upwardly, while flange 94 has its engagement surface 96 facing downwardly).
As best seen in
While the structures of end members 28 and 29, including flanges 88 and 94, have been illustrated in connection with a roof tile 11 having arcuate sections, the same structure and advantages are applicable to a flat tile 11, as best seen in
Referring to
A weather covering 101 for a roof structure 66 is formed with a plurality of tiles 11 of the present invention arranged in overlapping tiers. Each tier is formed by a plurality of tiles arranged in side-by-side relationship with their respective adjacent end members interlocked.
Referring to
A second tier 106 of tiles 11 (
Referring to
Referring to
While the variable thickness feature of the tile 121 has been illustrated and described in connection with a tile that is primarily a simple arcuate shape, it will be understood by those skilled in the art that that the same applies to any arcuate section of a tile, including those that are only a portion of the tile and not the entire tile such as the tile 11 of
In the prior art, as shown in
It will be understood by those skilled in the art that the materials involved do not permit geometric or dimensional precision and, thus, the modifier “generally” is used to accommodate the difference between ideal dimensions and geometric relationships and those possible in the real world. The roofing tiles described herein are designated by Underwriters Laboratories Inc.™ (UL) for installation as a Class A prepared roof covering under the UL790 standard for use on either combustible or noncombustible roof decks when the roofing surface is applied as intended. The combination of light weight (due to EPS composition) and superior fire resistance allows someone additional time to exit a burning building without fear of the roof caving in as it may in the case of heavier clay and concrete roofing tiles.
The roofing surface's Class A resistance to external fire provides significant assurances and greatly increases its effectiveness. The roofing tiles of the present invention have passed three rigorous UL certification tests to attain a Class A certification; specifically, the roofing tiles passed Intermittent Flame tests during which a 1400 degree F. gas flame was intermittently applied to the roofing tile during 15 four-minute cycles and a 12 mile-per-hour air current flowed over the roofing tile. No portion of the roofing tile was blown or fell off the roof deck in the form of flaming or glowing brands, nor was the roof deck exposed by breaking, sliding, cracking or warping of the roofing tiles. No part of the combustible 15/32″ plywood roof deck (the roof deck used during the certification process) fell away in the form of glowing particles, nor did it sustain flaming on its underside.
The roofing tiles of the present invention also passed Burning Brand tests in which a 12″×12″ brand was ignited and placed on the roofing tiles. Test observations were made until the brand was consumed and testing ceased. No portion of the roof tiles was blown or fell off the roof deck in the form of flaming or glowing brands, and the roofing tiles protected the roof deck such that it was not exposed by breaking, sliding, cracking or warping of the roofing surface. The underside of the roof deck experienced no sustained flaming, and no portions of the roof deck fell away in the form of glowing particles.
In a Spread of Flame test, the roofing tiles were exposed to a gas flame of 1400 degrees F. for ten minutes. With a maximum spread of flame of 3.5 feet and no significant lateral spread of the flame from the path directly exposed to the test flames, the roofing tiles of the present invention passed the test. As with the other tests, no portion of the tiles was blown or fell off the roof deck in the form of flaming or glowing brands, the roof deck was not exposed by breaking, sliding, cracking or warping of the roof surface, and no portions of the tiles fell away in the form of glowing particles.
Thus, the roofing tiles of the present invention are certified to carry the UL Class A listing mark for Prepared Roof Covering Materials. This certifies the roofing tiles of the present invention are effective against severe fire test exposures under which it affords a high degree of fire protection to the roof deck. The tiles are also certified not to slip from their position and are not expected to produce flying brands during severe fire test exposure. In sum, this significant degree of fire resistance is a particularly advantageous and effective feature of the roof tiles of the present invention.
The embodiments described provide a roofing surface that is certified Class A fire resistant under the stringent UL 790 standard. The tiles are strong, lightweight and resist insects, including termites and carpenter ants. The tiles promote a healthier environment because they are lightweight, which (1) cuts down on transportation exhaust emission and (2) requires less lumber to support the surface. Also, the foam used in the tiles act as an insulator that cuts down on construction costs (less insulation needed elsewhere, smaller heating and air conditioning equipment, etc.) and cuts down on the ongoing building energy needs.
Having described the methods and structures in detail and by reference to several preferred embodiments thereof, it will be apparent that modifications and variations are possible without departing from the scope of the invention defined in the following claims.
The present continuation patent application claims priority to pending U.S. patent application Ser. No. 12/803,365, filed Jun. 24, 2010, by inventors Carlos Torres and Wilbur Dale McIntire, which is a continuation-in-part patent application claiming priority to U.S. patent application Ser. No. 11/747,911, filed on May 13, 2007, by inventors Wilbur Dale McIntire and Carlos Torres (abandoned), which is a continuation-in-part of Ser. No. 11/348,173 filed on Feb. 6, 2006, by inventor Wilbur Dale McIntire (abandoned), which is a continuation-in-part of U.S. provisional patent application 60/717,608, filed on Sep. 17, 2005, by inventor Wilbur Dale McIntire.
Number | Date | Country | |
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Parent | 14246446 | Apr 2014 | US |
Child | 15450229 | US | |
Parent | 12803365 | Jun 2010 | US |
Child | 14246446 | US |
Number | Date | Country | |
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Parent | 11747911 | May 2007 | US |
Child | 12803365 | US | |
Parent | 11348173 | Feb 2006 | US |
Child | 11747911 | US | |
Parent | 60717608 | Sep 2005 | US |
Child | 11348173 | US |